Distinct accessory cell requirements define two types of rat T cell hybridomas specific for unique determinants in the encephalitogenic 68-86 region of myelin basic protein.

Six clonotypically unique T cell hybridomas from Lewis rats were used to study accessory cell activities required for class II MHC restricted T cell responses to the 68-86 encephalitogenic sequence of myelin basic protein (MBP). T cell hybrids which were cultured with GP68-86 68-86 sequence of guinea pig MBP (GPMBP) and naive splenocytes (SPL) were induced to produce IL-2 as measured by the CTLL indicator cell line. The hybrids were categorized into two subsets (designated THYB-1 and THYB-2), because two distinct subset-specific pathways of communication between accessory cells and T cells were involved in GPMBP-induced IL-2 production. These pathways were distinguished by the following six observations. First, when the duration of a pulse of SPL with GPMBP was lengthened from 1 to 4 h, these SPL lost their ability to induce IL-2 production by THYB-2 hybrids yet nevertheless retained full stimulatory activity for THYB-1 hybrids. Second, paraformaldehyde fixation of GPMBP-pulsed SPL abrogated an activity necessary for Ag-induced IL-2 production by THYB-2 hybrids. These fixed SPL were nevertheless able to stimulate THYB-1 hybrids, albeit to a lesser extent than viable unfixed SPL. Third, the addition of either cycloheximide, cytochalasin B, or 2-deoxyglucose to an Ag pulse of SPL with GPMBP dramatically inhibited the subsequent responses of THYB-2 hybrids yet had little or no effect upon the reactivity of THYB-1 hybrids. Fourth, thymocytes lacked necessary activities for GPMBP evoked IL-2 production by THYB-2 hybrids yet strongly promoted THYB-1 hybrid responses. Fifth, exposure of SPL to as little as 500 rad of gamma-irradiation markedly attenuated THYB-2 hybrid response to GPMBP but did not affect THYB-1 responses. Sixth, anti-GPMBP responses by THYB-2 hybrids were observed only in the presence of both radioresistant adherent SPL and a distinct population of radiosensitive nonadherent SPL. Conversely, THYB-1 hybrids exhibited full reactivity to GPMBP in the presence of adherent radioresistant SPL. Together, these observations reveal that two distinct accessory cell-T cell pathways mediate immune recognition of the 68-86 encephalitogenic region of MBP. Furthermore, these results indicate that subsets of Th cells can be defined by the accessory cell type-specific interactions that are necessary for Ag-mediated responses.     

Encephalitogenic and proliferative responses of Lewis rat lymphocytes distinguished by position 75- and 80-substituted peptides of myelin basic protein

The encephalitogenic and proliferative responses of Lewis rat lymphocytes were defined by use of synthetic peptide GP68-84, representing the 68-84 sequence of guinea pig myelin basic protein (GPMBP), and otherwise identical peptides containing substitutions of either A75 or P80 residues. The comparative activities of these peptides were tested in the following bioassays: 1) active induction of experimental autoimmune encephalomyelitis (EAE), 2) potentiation of EAE transfer activity by MBP- or peptide-sensitized lymph node cells (LNC), 3) in vitro proliferation of MBP- or peptide-sensitized LNC, and 4) in vitro proliferation of an encephalitogenic T cell line. The GP68-84 peptide exhibited potent activity in all four bioassays. In contrast, [A75]GP68-84 and [P80]GP68-84 exhibited a selective loss of certain activities while retaining activity in other bioassays. For example, LNC were activated by culture with [A75]GP68-84 to express potentiated EAE transfer activity. Furthermore, [A75]GP68-84 and GP68-84 were equipotent in stimulating the proliferation of the encephalitogenic T cell line. However, [A75]GP68-84 was virtually inactive in assays measuring the induction of EAE or the proliferation of either GPMBP- or [A75]GP68-84-sensitized LNC. Conversely, the [P80]GP68-84 peptide actively induced EAE and potentiated EAE cellular transfer activity but was incapable of stimulating proliferation of either GPMBP-sensitized LNC or an encephalitogenic T cell line. When [P80]GP68-84 was used for sensitization, in vitro proliferation of LNC was stimulated, but only by MBP sequences containing a P80 substitution. Overall, these results indicate that at least two structurally distinct T cell determinants of GP68-84 regulate functionally diverse encephalitogenic and proliferative activities of EAE-associated T cells.     

Specificity of T lymphocyte lines for peptides of myelin basic protein

T lymphocyte lines specific for myelin basic protein (BP) can mediate experimental autoimmune encephalomyelitis (EAE), or can protect against the active induction of the disease. To investigate the antigenic fine specificity of guinea pig (GP) BP-specific T cell lines raised from different rat strains, and to determine whether functionally different T lymphocyte lines and clones recognized the same or different regions of the BP molecule, the proliferation responses of line cells were assessed after stimulation with purified peptides of GP-BP. Lewis rat T cell lines and clones selected for responses to whole GP-BP responded selectively to the 68-88 amino acid sequence of GP-BP, but not to the 1-37, 43-67, or 89-169 sequences. The region of GP-BP recognized by Lewis T cells was additionally defined to include the 75-80 amino acid sequence, because a T cell clone responded equally to GP and rat BP which differed by only one amino acid at position 79, but did not respond to human or bovine BP, which had a Gly-His insertion in this region. T lymphocyte lines derived from the F344 and PVG (Weizmann) rat strains shared the same selective response to peptide 68-88, but lines from BN rats responded to an epitope(s) outside of the 68-88 sequence. The functional capacity of the various T cell lines to mediate experimental autoimmune encephalomyelitis (EAE) or to induce resistance against EAE was independent of their specificity for the different GP-BP peptides; lines specific for epitope(s) within or excluded from the 68-88 sequence could be encephalitogenic depending on their strain of origin, and various lines specific for the 68-88 peptide could induce both disease and protection, disease only, or neither activity.     

Genetic control of the development of experimental allergic encephalomyelitis in rats. Separation of MHC and non-MHC gene effects

Experimental allergic encephalomyelitis (EAE)-susceptible Lew and EAE-resistant Brown Norway (BN) rats and the corresponding MHC congenic strains were examined for their ability to develop clinical and histologic EAE. The ability of T cells from these animals to proliferate in vitro in response to whole guinea pig (GP) myelin basic protein (MBP), rat MBP, and to the major encephalitogenic peptide of GP MBP 66-88 (GP 68-88) was also assessed. We found that Lewis (Lew) was highly susceptible and showed good T cell responses to GP, MBP, rat MBP, and GP 68-88. Lew.1N (BN MHC on Lew background) and BN were not susceptible and T cells from these strains showed significant responses to GP MBP, but not to rat MBP or GP 68-88. Although BN.B1 (Lew MHC on BN background) was not susceptible to actively induced EAE, MBP-specific Lew T cells could transfer severe disease to BN.B1. BN.B1 T cells showed responses to GP-MBP, rat MBP, and GP 68-88 and, when transferred to naive BN.B1 or Lew, induced only mild clinical EAE in both strains. Increasing the number of T cells from BN.B1 had no effect on the severity of clinical symptoms in either recipient, suggesting some deficiency in the T cell repertoire that is necessary for induction of severe EAE. These results suggest that 1) the T cell response to rat MBP and GP68-88 (but not to sites other than 68-88 in GP MBP) is necessary for susceptibility to EAE; 2) the ability to respond to both rat MBP and GP 68-88 is determined by the MHC gene products on APC; and 3) given a permissive MHC, the T cell response that results in EAE is influenced by non-MHC genes.     

Modulation of outward K+ conductance is a post-activational event in rat T lymphocytes responsible for the adoptive transfer of experimental allergic encephalomyelitis

Experimental allergic encephalomyelitis (EAE) is an accepted animal model for the human demyelinating disease multiple sclerosis. The continuously propagated line of Lewis rat T helper lymphocytes (GP1 T cells), specific for the encephalitogenic 68–86 sequence of guinea pig myelin basic protein (GPMBP), mediates the adoptive transfer of EAE into normal syngeneic Lewis rats. Because mitogenic activation of T cells can increase K⁺ conductance, this study investigated changes in the outwardly rectifying K⁺ conductance in GP1 T cells following activation with the encephalitogen, GPMBP. Using the gigohm-seal whole-cell variation of the patch clamp technique, GP1 T cells were studied during a 3-day culture with GPMBP and throughout the subsequent 10 days, as cells progressed through both GPMBP-induced activation (EAE transfer activity) and proliferation responses, finally reverting to the resting state. Resting GP1 T cells exhibited peak K⁺ conductances around 2 nS, while GPMBP-induced activation resulted in 5- to 10-fold increases in peak K⁺ conductance, which temporally coincided with the optimal period of EAE transfer activity. During and immediately after the optimal period for EAE transfer, 20-mV depolarizing shifts in the voltage dependence of both activation and inactivation developed, abruptly reversing to resting values as cells reverted to the resting state. Accompanying the depolarizing shifts were a slowing of the K⁺ current activation kinetics and an acceleration of the deactivation kinetics. These results indicate that the K⁺ conductance in GP1 rat T helper cells is modulated over the full time course of GPMBP-induced cellular responses and that K⁺ channels should be optimally available during the period of adoptive EAE transfer, preceding disease manifestation.     

Indomethacin augments in vitro proliferative responses of Lewis rat lymphocytes to myelin basic protein. Implications for experimental autoimmune encephalomyelitis

Indomethacin (IM), a specific inhibitor of prostaglandin (PG) synthesis, and PGE2 were studied in terms of their ability to modulate in vitro immune responses associated with experimental autoimmune encephalomyelitis (EAE) in Lewis rats. Lymphoid cells from either the spleens or the draining lymph nodes of myelin basic protein (MBP)-sensitized rats exhibited in vitro immune responses which were enhanced in the presence of IM. Specifically, IM enhanced (i) guinea pig MBP (GPMBP)- and rat MBP (RMBP)-stimulated lymphocyte proliferation, (ii) background proliferation, and (iii) interleukin 2 (IL-2)-stimulated proliferation. Conversely, PGE2 inhibited both GPMBP- and IL-2-stimulated proliferation of MBP-sensitized lymphocytes. Together, these results indicate that PGs secreted by cultured lymphoid cells can directly mitigate MBP- or IL-2-stimulated lymphocyte proliferation. Furthermore, the observation that IM and PGE2 modulate in vitro responses of MBP-specific lymphocytes may provide insight into how the in vivo administration of IM potentiates the severity of EAE (H. Ovadia and P.Y. Paterson, Clin. Exp. Immunol. 49, 386, 1982) and how PGs may be involved in the spontaneous remission of EAE in rats.     

Suppression of experimental autoimmune encephalomyelitis by the oral administration of myelin basic protein

The oral administration of myelin basic protein (MBP) to Lewis rats prior to an encephalitogenic challenge resulted in total inhibition or a significant delay in the onset of experimental autoimmune encephalomyelitis (EAE). In vitro lymphocyte proliferative responses to MBP were significantly decreased in MBP-fed rats when compared with vehicle-fed controls. Suppression of EAE and in vitro proliferative responses to MBP were observed to be antigen specific, since oral feeding of a control protein exerted no suppressive effect. Moreover, the specificity of MBP-induced oral tolerance was shown to be species specific, since feeding guinea pig MBP (GPMBP) or human MBP (HuMBP) induced protection only against a GPMBP or HuMBP challenge, respectively. Conversely, Lewis rats could not be orally tolerized to the self antigen rat MBP.     

Autoreactive T cells persist in rats protected against experimental autoimmune encephalomyelitis and can be activated through stimulation of innate immunity

Lewis rats can be rendered unresponsive to experimental autoimmune encephalomyelitis by immunization with myelin basic protein (MBP), or MBP68-86, the dominant encephalitogenic MBP epitope for this strain, administered in IFA. However, protected rats harbor potentially encephalitogenic T cells, which are maintained in an inactive state. We investigated whether these quiescent effector cells could be activated in vitro. Although these T cells respond poorly to MBP68-86, they proliferate vigorously whether cocultured with MBP68-86 and either IL-2 or IL-12, suggesting that the T cells are in a state of anergy. Moreover, we could activate these anergic T cells with peptide and cytosine-guanine dinucleotide (CpG) oligonucleotide, but not control oligonucleotide, suggesting that products of the innate immune response are capable of activating anergic autoreactive T cells. The activated T cells produced the proinflammatory cytokine, IFN-gamma in response to IL-12, and IL-6 was secreted in response to CpG oligonucleotide. IL-6 has been reported to play a role in T cell activation by blocking T regulatory/suppressor (Treg) cell-mediated suppression through a Toll-like receptor-dependent pathway. However, anti-IL-6 mAb did not block CpG activation of the anergized cells. In contrast, anti-TGF-beta(1) Ab released the unresponsive T cells from the anergic state in the presence of MBP68-86, whereas TGF-beta(1) inhibited proliferation of MBP68-86- plus CpG-activated T cells. Because TGF-beta(1) has previously been implicated in Treg activity, this finding is consistent with a role for Treg cells in maintaining autoreactive T cells in the anergic state.     

Complete dissection of the Hb(64-76) determinant using T helper 1, T helper 2 clones, and T cell hybridomas.

We have generated cloned Th1 cells, Th2 cells, and T cell hybridomas specific for the single immunogenic peptide from the beta-chain of murine hemoglobin (Hb(64-76)). The availability of these various types of T cells provided us an unique opportunity to examine and dissect the T cell response to an immunogenic peptide. A panel of altered Hb peptides was made by replacing each amino acid in the Hb peptide (positions 64-76) with a conservative amino acid substitution or an alanine. Although none of the eleven T cell clones and hybridomas tested exhibited the same pattern of reactivity to the substituted Hb peptides, some general features were identified for all T cell responses. The primary T cell contact residue of Hb(64-76) was shown to be asparagine 72. For every Hb(64-76) specific T cell, no activation was observed using a peptide containing the conservative substitution of a glutamine for the asparagine at position 72. The flanking glutamic acid at position 73 was also required for a proliferative response for all of the Th1 and Th2 clones. The Th subtypes were not grossly unique in their responses to the substituted Hb peptides, but exhibited minor differences in fine specificity with the Th1 cells identifying more critical amino acids then did the Th2 cells. For the Th1 cells and also the T cell hybridomas, the phenylalanine at position 71 was critical for a T cell response. Analysis of peptide affinity for IEk molecules indicated that position 71 played a role in peptide binding to MHC. Secondary T cell contact residues, which were important for many but not all of the T cells, were identified at positions 69, 70, and 76. Overall T cell responses were minimally affected by changes in the amino acid residues at positions 64-68, 74, and 75. We have also demonstrated that cloned Th1 cells, Th2 cells and T hybridomas can be generated against the same Hb(64-76) determinant.     

Synthetic peptides from region 65–84 of bovine myelin basic protein: Radioimmunoassays and equilibrium competitive inhibition studies with antibodies prepared against myelin basic protein

Synthetic peptides with various and overlapping sequences represented by the residue region 65–84 of bovine myelin basic protein (MBP-bov) were tested in sodium sulfate radioimmunoassays for their reactivity with 15 rabbit antisera against MBPs from six different animal species and nine pools of syngeneic Lewis rat anti-MBP antisera. Three of the peptides were labeled with¹²⁵I and studied by direct binding reactions: (1) the prototype peptide S82 sequence TTHYG-SLPQKAQGHRPQDEG, corresponding to residues 65–84 of bovine MBP except for the C-terminal glycine, which is encephalitogenic in rabbits: (2) S81, which lacks the first three residues of S82 and is nonencephalitogenic in rabbits; and (3) S79, which represents the C-terminal half of S82 and which, because of its C-terminal glycine instead of asparagine, is nonencephalitogenic in Lewis rats. Fourteen of the rabbit anti-MBP antisera were reactive with [¹²⁵I]S82 (two borderline) including 2 of 3 antisera against human MBP, one against monkey MBP, and one against chicken MBP. The cross-reactions with [¹²⁵I]S81 were somewhat fewer and less intense. There were no cross-reactions with [¹²⁵I]S79. None of nine different pools of syngeneic rat MBP antisera cross-reacted with any of the three labeled peptides. With the use of a rabbit anti-MBP-rat antiserum that crossreacted strongly with [¹²⁵I]S82, 15 additional peptides with overlapping sequences within the residue region 65–84, as well as five MBP preparations from four different species, were tested by equilibrium and nonequilibrium competitive inhibition RIAs. Unlabeled S82 and MBP-bov were completely competitive with [¹²⁵I]S82 in the equilibrium assays; S81 and three other peptides had low degrees of cross-reactivity; but none of the remaining eight unlabeled peptides or unlabeled MBP preparations of guinea pig, rat, or mouse origin gave any evidence of competitive activity. Nonequilibrium competitive inhibition RIAs, however, did reveal cross-reactivities among several of the peptides as well as guinea pig and rat MBP. It was concluded that the N-terminal half of S82, particularly residues 68–74 (YGSLPQK), must contain an immunodeterminant of amino acid residues which identifies with the corresponding and exposed sequence in intact MBP-bov.This research was supported at Duke University by research grants 833-E-5 from the National Multiple Sclerosis Society and NS-10237 from the National Institutes of Health of the U.S. Public Health Service; at St. Luke's Hospital Center and Columbia University by grant RG1197-A-5 from the National Multiple Sclerosis Society; and at Northwestern University by grant NS-06262 from the National Institutes of Health of the U.S. Public Health Service.     

Cross-reactivity of T-cell clones specific for altered peptide ligands of myelin basic protein

We have determined that certain altered peptide ligands (APLs) can induce T-cells specific for the native peptide myelin basic protein (MBP) p85-99 to secrete Th2-type cytokines such as IL-4 and IL-5 in the absence of significant Th1-type cytokines. However, it is not known whether stimulation with APLs will activate autoreactive T cells or a distinct population of cells. In the present study, 18 T-cell clones that reacted with either MBP p85-99 or one of three APLs of the peptide substituted at TCR contact residues were generated. T-cells were tested functionally for their reactivity to the original stimulating peptide as well as to the MBP APLs. In addition, the T-cell receptor (TCR) alpha and beta chains of each of these clones were sequenced. In a series of T-cell clones isolated from a multiple sclerosis patient, stimulation of T-cells with the APL 93A, which has an alanine for lysine substitution at the TCR contact residue 93, did not induce substantial proliferation of MBPp85-99-specific T-cell clones, indicating that a distinct set of T-cell clones was induced. However, this was not the case for another set of T-cell clones from a different individual in which the 93A peptide induced clonal expansion of T-cells highly reactive with the native MBPp85-99 antigen. Thus, the potential beneficial effect of using APLs to induce downregulatory cytokines appears to depend on the specific T-cell repertoire of the individual patient.     

Characterization of the antigen specificity and TCR repertoire,and TCR-based DNA vaccine therapy in myelin basic protein-induced autoimmune encephalomyelitis in DA rats

Like Lewis rats, DA rats are an experimental autoimmune encephalomyelitis (EAE)-susceptible strain and develop severe EAE upon immunization with myelin basic protein (MBP). However, there are several differences between the two strains. In the present study we induced acute EAE in DA rats by immunization with MBP and MBP peptides and examined the Ag specificity and TCR repertoire of encephalitogenic T cells. It was found that although immunization with MBP and a peptide corresponding to its 62-75 sequence (MBP(62-75)) induced clinical EAE, the responses of lymph node T cells isolated from MBP-immunized rats to MBP(62-75) was marginal, indicating that this peptide contains major encephalitogenic, but not immunodominant, epitopes. The TCR analysis by CDR3 spectratyping of spinal cord T cells revealed that Vbeta10 and Vbeta15 spectratype expansion was always found in MBP(62-75)-immunized symptomatic rats. On the basis of these findings, we examined the encephalitogenicity of Vbeta10- and Vbeta15-positive T cells. First, the adoptive transfer experiments revealed that Vbeta10-positive T line cells derived from MBP(62-75)-immunized rats induced clinical EAE in recipients. Second, administration of DNA vaccines encoding Vbeta10 and Vbeta15, alone or in combination, ameliorated MBP(62-75)-induced EAE. Collectively, it was strongly suggested that Vbeta10- and Vbeta15-positive T cells are encephalitogenic. Analyses of the Ag specificity and T cell repertoire of pathogenic T cells performed in this study provide useful information for designing specific immunotherapies against autoimmune diseases.     

Encephalitogenic T cell clones with variant receptor specificity

We explored antigenic differences between guinea pig (GP)-basic protein (BP), rat (Rt)-BP, and respective peptides from the encephalitogenic region for Lewis rats by comparing the fine specificity of T lymphocyte lines and clones selected from animals primed with these Ag. Encephalitogenic T cell lines specific for GP-BP or Rt-BP predictably recognized the corresponding 72-89 and to a lesser degree the 72-84 (S55S) amino acid sequence. T cell lines selected from rats primed with GP-S55S responded preferentially to GP-S55S compared to other peptides. A T cell line raised to Rt-S55S, however, initially recognized the S55S and S72-89 peptides but were nearly unresponsive to the intact GP-BP or Rt-BP. T cell clones selected from the Rt-S55S line at that point had two distinct patterns of response: clones that recognized both of the BP and the S55S peptides adoptively transferred delayed-type hypersensitivity and experimental autoimmune encephalomyelitis. These clones also recognized residues 69-81 (S67) but not peptide S75-89. In contrast, T cell clones that responded only to synthetic peptides GP-S55S and Rt-S55S but not to the parent BP adoptively transferred delayed-type hypersensitivity but not disease in Lewis rats. The same clones failed to respond to either the S67 or the S75-89 sequences. These results demonstrate that the encephalitogenic Rt-S55S sequence houses a minimum of two T cell epitopes with differing specificities and functions. One epitope is immuno-dominant and resembles the encephalitogenic region of the intact BP molecule. The second non-encephalitogenic epitope is restricted to the S55S sequences and is not shared by the parent BP, the S67, or the S75-89 sequences. Both types of Rt-S55S-specific clones differ in fine specificity from encephalitogenic clones selected from GP-BP immunized rats, thus indicating that uniformity of T cell recognition of the encephalitogenic epitope is not an absolute condition for T cells to be encephalitogenic.     

The major site of guinea-pig myelin basic protein encephalitogenic in Lewis rats.

In the Lewis rat, fragment 43–88 of the highly encephalitogenic guinea-pig basic protein has been previously shown to retain the full activity of the parent protein. In the present studies this fragment was subjected to controlled chymotryptic digestion so that cleavage occurred only at tyrosine 67, generating two peptides, residues 43-67 and residues 68-88. When compared on an equimolar basis peptide 68-88 had the same encephalitogenic activity as the intact fragment and induced the same degree of immunologically specific cell response as measured by the in vitro lymphocyte stimulation test. Peptide 68-88 was further fragmented by selective tryptic cleavage at arginine 78 after blocking lysine 73 with citraconic anhydride. The two peptides, residues 68-78 and residues 79-88, were not encephalitogenic, indicating that residues adjacent to the point of cleavage contribute to the active site.     

Interleukin 1 and myelin basic protein synergistically augment adoptive transfer activity of lymphocytes mediating experimental autoimmune encephalomyelitis in Lewis rats

This investigation focused on the role of adherent accessory cells and their cellular product, interleukin 1 (IL 1), in cellular immune responses associated with experimental autoimmune encephalomyelitis (EAE) in Lewis rats. Guinea pig myelin basic protein (GPMBP)-sensitized lymph node cells (LNC) responded in culture with GPMBP by undergoing activation as measured by augmented transfer of EAE to syngeneic recipients, and proliferation as measured by [3H]thymidine incorporation. GPMBP-sensitized LNC, after depletion of adherent accessory cells, no longer responded to GPMBP in the EAE transfer activation assay. In contrast, aliquots of the same LNC preparation exhibited proliferative responses to GPMBP that were only partially reduced. Addition of irradiated thymocytes to adherent cell-depleted cultures fully reconstituted responsiveness to GPMBP in the activation assay and restored full reactivity to GPMBP in the proliferation assay. Furthermore, addition of either purified human IL 1 or recombinant human IL 1 to adherent cell-depleted cultures reconstituted reactivity to GPMBP in the EAE transfer activation assay and augmented GPMBP-specific proliferative responses. Anti-Ia monoclonal antibodies blocked GPMBP + IL 1-induced cellular activation of nonadherent LNC. These results demonstrate that both IL 1 and Ia molecules are important in the pathway leading to GPMBP-induced activation of EAE-inducing T lymphocytes. Furthermore, these results suggest that different accessory signals may be required for optimal induction of GPMBP-induced lymphocyte activation vs GPMBP-specific proliferative responses.     

The immune response of Lewis rats to peptide 68-88 of guinea pig myelin basic protein. I. T cell determinants.

A series of peptides, produced from peptide 68-88 by selective enzyme cleavage, were used to define the amino acid sequences required for the induction of experimental allergic encephalomyelitis (EAE), an in vitro lymphocyte proliferative response (LPR), and serum antibody by peptide 68-88 in the Lewis rat. Here we present data that indicate that the T cell determinants for induction of EAE, an LPR, and helper function in the production of antibody are located in the same region of the molecule and that a minimum of 13 amino acids are involved; i.e., residues 71-85.     

Characterization of the immune response to a secondary encephalitogenic epitope of basic protein in Lewis rats. I. T cell receptor peptide regulation of T cell clones expressing cross-reactive V beta genes.

In Lewis rats, immunization with myelin basic protein induces two distinct encephalitogenic T cell populations, those responding to the immunodominant 72-89 epitope and those specific for a secondary epitope including residues 87-99. The 72-89 specific T cells were I-A restricted and preferentially expressed V beta 8.2 in their TCR. To determine the fine specificity, MHC restriction, and TCR V beta gene use in T cells reactive to the secondary epitope, we characterized 23 T cell clones from the lymph nodes (LN) and spinal cords (SC) of rats immunized with either whole basic protein or synthetic peptides S85-99 and S87-99 that were found to be functionally similar. The S85-99/S87-99 specific clones from LN and SC were all encephalitogenic despite differences in recognition of intact basic protein and class II MHC restriction. Unlike LN clones that overexpressed V beta 8 (46%+) and V beta 6 (31%+), however, SC clones were strongly biased (86%+) in their expression of V beta 6. This V gene bias raised the possibility of TCR peptide therapy using V beta 6 peptides. The V beta 6 sequence was similar to V beta 8.2 in the CDR2 region, and the corresponding peptides from this region were found to be cross-reactive in vivo. Moreover, both peptides were effective in the treatment of EAE induced with either S85-99, biased in V beta 6+ and V beta 8+ T cells, or guinea pig basic protein, biased only in V beta 8+ T cells. These data demonstrate the presence of common immunogenic epitopes among subsets of TCR V region gene families that possess important regulatory activity on effector T cell function.     

Cleavage specificity of a myofibril-bound serine proteinase from carp (Cyprinus carpio) muscle

Previously, we reported the purification and characterization of a myofibril-bound serine proteinase (MBP) from carp muscle (Osatomi K, Sasai H, Cao M-J, Hara K, Ishihara T. Comp Biochem Physiol 1997;116B:159–66). In the present study, the N-terminal amino acid sequence of the enzyme was determined, which showed high identity with those of other trypsin-like serine proteases. The cleavage specificity of MBP for dibasic and monobasic residues was investigated using various fluorogenic substrates and peptides. Analyses of the cleaved peptide products showed that the enzyme hydrolyzed peptides both at monobasic and dibasic amino acid residues. Monobasic amino acid residues were hydrolyzed at the carboxyl side; dibasic residues were cleaved either at the carboxyl side of the pair or between the two basic residues and the enzyme showed a cleavage preference for the Arg-Arg pair. Unexpectedly, MBP hydrolyzed lysyl-bradykinin and methionyl–lysyl–bradykinin at the carboxyl side of Gly fairly specifically and efficiently displaying a unique cleavage. Because MBP also degraded protein substrates such as casein and myofibrillar proteins, the substrate specificity of MBP appeared not to be strictly specific.     

Regulation of the effector stages of experimental autoimmune encephalomyelitis via neuroantigen-specific tolerance induction. II. Fine specificity of effector T cell inhibition.

Ag-specific tolerance induced by the i.v. administration of splenocytes coupled with mouse spinal cord homogenate, containing a mixture of myelin Ag, dramatically inhibits development and expression of clinical and histologic signs of both active and adoptive forms of relapsing experimental autoimmune encephalomyelitis (R-EAE) in the SJL/J host. Here we examined the dose-dependency, route of tolerogen administration, and fine neuroantigen specificity of inhibition of adoptive R-EAE. Expression of clinical R-EAE induced by a polyclonal population of bovine myelin basic protein (MBP)-specific effector T cells was dramatically inhibited in a dose-dependent manner following the i.v., but not s.c. or i.p., injection of MBP-coupled splenocytes. The exquisite Ag specificity of the inhibition was evident by the observation that splenocytes coupled with intact bovine MBP or species variants of MBP homologous with bovine MBP within the major encephalitogenic region (amino acids 84-104), but not with proteolipid protein or mouse kidney homogenate, were able to suppress disease expression. Splenocytes coupled with the MBP84-104 peptide, containing a nested set of the major SJL/J encephalitogenic epitopes, completely inhibited peptide-specific T cell responses, but only partially inhibited the expression of disease transferred by T cells specific for intact MBP, suggesting the participation of T cell responses specific for additional MBP determinants in disease pathogenesis. However, splenocytes coupled with previously identified minor SJL/J encephalitogenic epitopes (MBP91-104 or MBP17-27), or with the Lewis rat major encephalitogenic epitope (MBP68-86), did not suppress disease expression. Collectively, the results demonstrate that MBP84-104-specific T cells and T cells specific for an as yet unidentified MBP epitope(s) contribute to the pathology of R-EAE. In addition, the results demonstrate that peptide-specific tolerance induction appears to have potential for the treatment of T cell-mediated inflammatory diseases.     

An Antibody Specific for Component 8 of Myelin Basic Protein from Normal Brain Reacts Strongly with Component 8 from Multiple Sclerosis Brain

Myelin basic protein (MBP) consists of several components or charge isomers (C-1 through C-8) generated by one or a combination of posttranslational modifications. One of these, C-8, has been shown to contain citrulline (Cit) at defined sites formed by deimination of six arginyl residues. This unusual modification has allowed us to raise antibodies specific for this charge isomer only. To do this, a synthetic peptide, Gly-Cit-Cit-Cit-Cit, was coupled to keyhole limpet hemocyanin and injected into rabbits. The antibodies so generated reacted only with C-8 and not with any of the other charge isomers. A second antibody fraction was raised against the synthetic peptide ACitHGFLPCitHR naturally occurring between residues 24 and 33 of C-8 (all other charge isomers contain R instead of Cit at positions 25 and 31). These antibodies preferred C-8 but reacted with the other charge isomers, to the extent of approximately 25-30% of the reactivity shown with C-8. In studies with C-8 from multiple sclerosis (MS) MBP, much greater reactivity was obtained with these antibodies when compared with their reactivity with C-8 from normal MBP. Because the total number of Cit residues in C-8 from MS and normal MBP is the same, the difference in reactivity may be related to structural factors. The antibodies raised with the tetra-Cit peptide were reacted with three pairs of synthetic peptides: 24ARHGFLPRHR33 and ACitHGFLPCitHR; 120GQRPGFGYGGRAS132 and GQCitPGFGYGGCitAS; and 157GGRDSRSGSPMARR170 and GGCitDSRSGSPMACitR. They reacted only with the Cit-containing peptides in the order 157-170 greater than 120-130 greater than 24-33.(ABSTRACT TRUNCATED AT 250 WORDS)